Complementation of bacteriophage lambda integrase mutants: evidence for an intersubunit active site.

Site-specific recombination of bacteriophage lambda starts with the formation of higher-order protein--DNA complexes, called 'intasomes', and is followed by a series of steps, including the initial DNA cleavage, top-strand exchange, branch migration and bottom-strand exchange, to produce recombinant products. One of the intasomes formed during excisive recombination (the attL complex) is composed of the phage-encoded integrase (Int), integration host factor (IHF) and one of the recombination substrates, attL DNA. Int is the catalytic recombinase and has two different DNA binding domains. When IHF is present, Int binds to two types of sites in attL DNA, the three arm-type sites (P'123) and the core-type sites (B and C') where the reciprocal strand exchange takes place. The Tyr342 residue of Int serves as a nucleophile during strand cleavage and covalently attaches to the DNA through a phosphotyrosyl bond. In vitro complementation assays have been performed for strand cleavage using attL suicide substrates and mutant proteins containing amino acid substitutions at residues conserved in the integrase family of recombinases. We demonstrate that at least two Int monomers are required to form the catalytically-competent species that performs cleavage at the B site. It is likely that the active site is formed by two Int monomers.     

Half-att site substrates reveal the homology independence and minimal protein requirements for productive synapsis in lambda excisive recombination

The early events in site-specific excisive recombination were studied with phage lambda half-att sites that have no DNA to one side of the strand exchange region; they carry a single core-type integrase binding site and either P or P' arm flanking DNA. These half-attR and half-attL sites exhibit normal properties for the initial (covalent) top-strand transfer and form stable intermediates independent of later steps in the reaction. With these novel substrates we show that Xis specifically promotes the first strand exchange and that attL enhances Int cleavage at the top-strand site of attR. It is also shown that synapsis and initial strand transfers do not require DNA-DNA pairing but are mediated by protein-protein and protein-DNA interactions. These involve the two top-strand Int binding sites (required for the first strand exchange) and, in addition, one of the two bottom-strand sites (C') responsible for the second strand exchange.     

DNA arms do the legwork to ensure the directionality of lambda site-specific recombination

The integrase protein of bacteriophage lambda (Int) catalyzes site-specific recombination between lambda phage and Escherichia coli genomes. Int is a tyrosine recombinase that binds to DNA core sites via a C-terminal catalytic domain and to a collection of arm DNA sites, distant from the site of recombination, via its N-terminal domain. The arm sites, in conjunction with accessory DNA-bending proteins, provide a means of regulating the efficiency and directionality of Int-catalyzed recombination. Recent crystal structures of lambda Int tetramers bound to synaptic and Holliday junction intermediates, together with new biochemical data, suggest a mechanism for the allosteric control of the recombination reaction through arm DNA binding interactions.     

Interactions between integrase and excisionase in the phage lambda excisive nucleoprotein complex

Bacteriophage lambda site-specific recombination comprises two overall reactions, integration into and excision from the host chromosome. Lambda integrase (Int) carries out both reactions. During excision, excisionase (Xis) helps Int to bind DNA and introduces a bend in the DNA that facilitates formation of the proper excisive nucleoprotein complex. The carboxyl-terminal alpha-helix of Xis is thought to interact with Int through direct protein-protein interactions. In this study, we used gel mobility shift assays to show that the amino-terminal domain of Int maintained cooperative interactions with Xis. This finding indicates that the amino-terminal arm-type DNA binding domain of Int interacts with Xis.     

Site-specific recombination in eukaryotic cells mediated by mutant lambda integrases: implications for synaptic complex formation and the reactivity of episomal DNA segments

Mutant lambda integrases catalyze site-specific DNA recombination in the absence of accessory factors IHF, XIS, and negative DNA supercoiling. Here we investigate the effects that a human cellular environment exerts on these reactions in order to (i) gain further insights into mechanistic aspects of recombination in eukaryotic cells and (ii) to further develop the Int system for biotechnological applications. First, we compared intra- and intermolecular integrative as well as excisive recombination pathways on episomal substrates after co-transfection with recombinase expression vectors. Our results demonstrate that, within 24 hours after transfection, intermolecular recombination by mutant integrase is at least as efficient as intramolecular recombination. Second, a significant intermolecular recombination activity was observed between two copies of a recombination site containing only the 21 bp comprising core-type DNA sequence. This basic activity was stimulated several-fold when arm-type DNA sequences were present in addition to core sites. Therefore, one recombination pathway in human cells involves mutant integrases bound solely at core sites, which is reminiscent of the Flp/FRT and Cre/loxP pathways. The stimulatory effect of arm-type sequences could be explained by an increase in integrase concentration in the vicinity of core sites. We show, in addition, that an N-terminal truncated mutant integrase exhibited only a very weak recombinogenic activity in a eukaryotic background. This result strengthens a functional role for the N-terminal domain in recombination in addition to its arm-type DNA-binding activity. Finally, we demonstrate that low level integrative recombination by wild-type integrase is stimulated when purified integration host factor is co-transfected. This corroborates our previous conclusion that sufficient amounts of eukaryotic protein co-factors, which could functionally replace IHF, are not present in human cells. It also provides a potential means to control site-specific recombination in eukaryotic cells.     

Site-specific recombination in human cells catalyzed by phage lambda integrase mutants

Phage lambda Integrase (Int) is the prototype of the so-called integrase family of conservative site-specific recombinases, which includes Cre and FLP. The natural function of Int is to execute integration and excision of the phage into and out of the Escherichia coli genome, respectively. In contrast to Cre and FLP, however, wild-type Int requires accessory proteins and DNA supercoiling of target sites to catalyze recombination. Here, we show that two mutant Int proteins, Int-h (E174 K) and its derivative Int-h/218 (E174 K/E218 K), which do not require accessory factors, are proficient to perform intramolecular integrative and excisive recombination in co-transfection assays inside human cells. Intramolecular integrative recombination is also detectable by Southern analysis in human reporter cell lines harboring target sites attB and attP as stable genomic sequences. Recombination by wild-type Int, however, is not detectable by this method. The latter result implies that eukaryotic co-factors, which could functionally replace the prokaryotic ones normally required for wild-type Int, are most likely not present in human cells.     

Mutations in the amino-terminal domain of lambda-integrase have differential effects on integrative and excisive recombination

Lambda integrase (Int) forms higher-order protein-DNA complexes necessary for site-specific recombination. The carboxy-terminal domain of Int (75-356) is responsible for catalysis at specific core-type binding sites whereas the amino-terminal domain (1-70) is responsible for cooperative arm-type DNA binding. Alanine scanning mutagenesis of residues 64-70, within full-length integrase, has revealed differential effects on cooperative arm binding interactions that are required for integrative and excisive recombination. Interestingly, while these residues are required for cooperative arm-type binding on both P'1,2 and P'2,3 substrates, cooperative binding at the arm-type sites P'2,3 was more severely compromised than binding at arm-type sites P'1,2 for L64A. Concomitantly, L64A had a much stronger effect on integrative than on excisive recombination. The arm-binding properties of Int appear to be intrinsic to the amino-terminal domain because the phenotype of L64A was the same in an amino-terminal fragment (Int 1-75) as it was in the full-length protein.     

Characterization of the bacteriophage lambda excisionase (Xis) protein: the C-terminus is required for Xis-integrase cooperativity but not for DNA binding.

We have performed a mutational analysis of the xis gene of bacteriophage lambda. The Xis protein is 72 amino acids in length and required for excisive recombination. Twenty-six mutants of Xis were isolated that were impaired or deficient in lambda excision. Mutant proteins that contained amino acid substitutions in the N-terminal 49 amino acids of Xis were defective in excisive recombination and were unable to bind DNA. In contrast, one mutant protein containing a leucine to proline substitution at position 60 and two truncated proteins containing either the N-terminal 53 or 64 amino acids continued to bind lambda DNA, interact cooperatively with FIS and promote excision. However, these three mutants were unable to bind DNA cooperatively with Int. Cooperativity between wild-type Xis and Int required the presence of FIS, but not the Int core-type binding sites. This study shows that Xis has at least two functional domains and also demonstrates the importance of the cooperativity in DNA binding of FIS, Xis and Int in lambda excision.     

In vitro packaging into phage T4 particles and specific recircularization of phage lambda DNAs

Concatemeric phage lambda imm434 DNA packaged in vitro into phage T4 particles produced plaques on a selective host. Moreover, lambda DNA containing a pBR322 derivative flanked by the lambda attL and attR sites could be specifically recircularized by excisive lambda recombination to yield the pBR322 derivative. A host deficient in generalized recombination and containing a defective lambda c Its prophage which provided Int and Xis proteins was the recipient for this plasmid derivative carried by T4. Such a T4-lambda hybrid may potentially allow almost one T4 headful of donor DNA (166 kb) to be packaged and recircularized.     

Directional control of site-specific recombination by bacteriophage lambda. Evidence that a binding site for Int protein far from the crossover point is required for integrative but not excisive recombination

Phage lambda controls its integration and excision by differential catalysis of the forward and reverse reactions. The lambda Int protein is required for both directions, but Xis for excision only. To investigate the substrate requirements for directional control, we have characterized two mutations of the phage attachment site that are defective in integrative but not excisive recombination. Both of these mutations produce the same base change in the P'3 binding site for Int protein 79 base-pairs from the center of the crossover region for site-specific recombination. We infer that differential utilization of this distant binding site is crucial for directional control of recombination.     

Arm sequences contribute to the architecture and catalytic function of a lambda integrase-Holliday junction complex

lambda integrase (Int) mediates recombination between attachment sites on lambda phage and E. coli DNAs. With the assistance of accessory proteins that induce DNA loops, Int bridges pairs of distinct arm- and core-type DNA binding sites to form synapsed recombination complexes, which then recombine via a Holliday junction (HJ) intermediate. We show that, in addition to promoting the proper positioning of Int protomers, the arm sequences facilitate the catalytic activities of the Int tetramer, independent of accessory proteins or physical continuity between the arm and core sites. We have determined the architecture of ternary complexes containing a HJ, Int, and P'1,2 arm-type DNA. These structures accommodate simultaneous binding of Int to direct-repeat arm sites and indirect-repeat core sites and afford a new view of the higher-order recombinogenic complexes.     

The geometry of a synaptic intermediate in a pathway of bacteriophage lambda site-specific recombination.

Bacteriophage lambda uses site-specific recombination to move its DNA into and out of the Escherichia coli genome. The recombination event is mediated by the phage-encoded integrase (Int) at short DNA sequences known as attachment ( att ) sites. Int catalyzes recombination via at least four distinct pathways, distinguishable by their requirements for accessory proteins and by the sequence of their substrates. The simplest recombination reaction catalyzed by Int does not require any accessory proteins and takes place between two attL sites. This reaction proceeds through an intermediate known as the straight-L bimolecular complex (SL-BMC), a stable complex which contains two attL sites synapsed by Int. We have investigated the orientation of the two substrates in the SL-BMC with respect to each other using two independent direct methods, a ligation assay and visualization by atomic force microscopy (AFM). Both show that the two DNA substrates in the complex are arranged in a tetrahedral or nearly square planar alignment skewed towards parallel. The DNA molecules in the complex are bent.     

Mutations at residues 282, 286, and 293 of phage lambda integrase exert pathway-specific effects on synapsis and catalysis in recombination

Bacteriophage lambda integrase (Int) catalyzes site-specific recombination between pairs of attachment (att) sites. The att sites contain weak Int-binding sites called core-type sites that are separated by a 7-bp overlap region, where cleavage and strand exchange occur. We have characterized a number of mutant Int proteins with substitutions at positions S282 (S282A, S282F, and S282T), S286 (S286A, S286L, and S286T), and R293 (R293E, R293K, and R293Q). We investigated the core- and arm-binding properties and cooperativity of the mutant proteins, their ability to catalyze cleavage, and their ability to form and resolve Holliday junctions. Our kinetic analyses have identified synapsis as the rate-limiting step in excisive recombination. The IntS282 and IntS286 mutants show defects in synapsis in the bent-L and excisive pathways, respectively, while the IntR293 mutants exhibit synapsis defects in both the excision and bent-L pathways. The results of our study support earlier findings that the catalytic domain also serves a role in binding to core-type sites, that the core contacts made by this domain are important for both synapsis and catalysis, and that Int contacts core-type sites differently among the four recombination pathways. We speculate that these residues are important for the proper positioning of the catalytic residues involved in the recombination reaction and that their positions differ in the distinct nucleoprotein architectures formed during each pathway. Finally, we found that not all catalytic events in excision follow synapsis: the attL site probably undergoes several rounds of cleavage and ligation before it synapses and exchanges DNA with attR.     

Control and regulation of KplE1 prophage site-specific recombination: a new recombination module analyzed

KplE1 is one of the 10 prophage regions of Escherichia coli K12, located at 2464 kb on the chromosome. KplE1 is defective for lysis, but it is fully competent for excisive recombination. In this study, we have mapped the binding sites of the recombination proteins, namely IntS, TorI, and IHF on attL and attR, and the organization of these sites suggests that the intasome is architecturally different from the lambda canonical form. We also measured the relative contribution of these proteins to both excisive and integrative recombination by using a quantitative in vitro assay. These experiments show a requirement of the TorI excisionase for excisive recombination and of the IntS integrase for both integration and excision. Moreover, we observed a strong influence of the supercoiled state of the substrates. The KplE1 recombination module, composed of the integrase and excisionase genes together with the attL and attR DNA regions, is highly similar to that of several phages infecting various E. coli strains as well as Shigella flexneri and Shigella sonnei. The in vitro recombination data reveal that HK620 and KplE1 att sequences are exchangeable. This study thus defines a new site-specific recombination module, and implications for the mechanism and regulation of recombination are discussed.     

Conjugative transposition: Tn916 integrase contains two independent DNA binding domains that recognize different DNA sequences.

Transposition of the conjugative transposon Tn916 requires the activity of a protein, called Int, which is related to members of the integrase family of site-specific recombinases. This family includes phage lambda integrase as well as the Cre, FLP and XerC/XerD recombinases. Different proteins, consisting of fragments of Tn916 Int protein fused to the C-terminal end of maltose binding protein (MBP) were purified from Escherichia coli. DNase I protection experiments showed that MBP-INT proteins containing the C-terminal end of Int bound to the ends of the transposon and adjacent plasmid DNA. MBP-INT proteins containing the N-terminal end of Int bound to sequences within the transposon close to each end. Competition binding experiments showed that the sites recognized by the C- and N-terminal regions of Int did not compete with each other for binding to MBP-INT. We suggest that Tn916 and related conjugative transposons are unique among members of the integrase family of site-specific recombination systems because the presence of two DNA binding domains in the Int protein might allow Int to bridge recombining sites, and this bridging seems to be the sole mechanism ensuring that only correctly aligned molecules undergo recombination.     

Active-site assembly and mode of DNA cleavage by Flp recombinase during full-site recombination.

A combination of half-site substrates and step arrest mutants of Flp, a site-specific recombinase of the integrase family, had earlier revealed the following features of the half-site recombination reaction. (i) The Flp active site is assembled by sharing of catalytic residues from at least two monomers of the protein. (ii) A Flp monomer does not cleave the half site to which it is bound (DNA cleavage in cis); rather, it cleaves a half site bound by a second Flp monomer (DNA cleavage in trans). For the lambda integrase (Int protein), the prototype member of the Int family, catalytic complementation between two active-site mutants has been observed in reactions with a suicide attL substrate. By analogy with Flp, this observation is strongly suggestive of a shared active site and of trans DNA cleavage. However, reactions with linear suicide attB substrates and synthetic Holliday junctions are more compatible with cis than with trans DNA cleavage. These Int results either argue against a common mode of active-site assembly within the Int family or challenge the validity of Flp half sites as mimics of the normal full-site substrates. We devised a strategy to assay catalytic complementation between Flp monomers in full sites. We found that the full-site reaction follows the shared active-site paradigm and the trans mode of DNA cleavage. These results suggest that within the Int family, a unitary chemical mechanism of recombination is achieved by more than one mode of physical interaction among the recombinase monomers.     

A biotin interference assay highlights two different asymmetric interaction profiles for lambda integrase arm-type binding sites in integrative versus excisive recombination

The site-specific recombinase integrase encoded by bacteriophage lambda promotes integration and excision of the viral chromosome into and out of its Escherichia coli host chromosome through a Holliday junction recombination intermediate. This intermediate contains an integrase tetramer bound via its catalytic carboxyl-terminal domains to the four "core-type" sites of the Holliday junction DNA and via its amino-terminal domains to distal "arm-type" sites. The two classes of integrase binding sites are brought into close proximity by an ensemble of accessory proteins that bind and bend the intervening DNA. We have used a biotin interference assay that probes the requirement for major groove protein binding at specified DNA loci in conjunction with DNA protection, gel mobility shift, and genetic experiments to test several predictions of the models derived from the x-ray crystal structures of minimized and symmetrized surrogates of recombination intermediates lacking the accessory proteins and their cognate DNA targets. Our data do not support the predictions of "non-canonical" DNA targets for the N-domain of integrase, and they indicate that the complexes used for x-ray crystallography are more appropriate for modeling excisive rather than integrative recombination intermediates. We suggest that the difference in the asymmetric interaction profiles of the N-domains and arm-type sites in integrative versus excisive recombinogenic complexes reflects the regulation of recombination, whereas the asymmetry of these patterns within each reaction contributes to directionality.     

The Escherichia coli Fis protein stimulates bacteriophage lambda integrative recombination in vitro

The Escherichia coli nucleoid-associated protein Fis was previously shown to be involved in bacteriophage lambda site-specific recombination in vivo, enhancing the levels of both integrative recombination and excisive recombination. While purified Fis protein was shown to stimulate in vitro excision, Fis appeared to have no effect on in vitro integration reactions even though a 15-fold drop in lysogenization frequency had previously been observed in fis mutants. We demonstrate here that E. coli Fis protein does stimulate integrative lambda recombination in vitro but only under specific conditions which likely mimic natural in vivo recombination more closely than the standard conditions used in vitro. In the presence of suboptimal concentrations of Int protein, Fis stimulates the rate of integrative recombination significantly. In addition, Fis enhances the recombination of substrates with nonstandard topologies which may be more relevant to the process of in vivo phage lambda recombination. These data support the hypothesis that Fis may play an essential role in lambda recombination in the host cell.     

Mapping of a higher order protein-DNA complex: two kinds of long-range interactions in lambda attL

To map the protein-protein and protein-DNA interactions involved in lambda site-specific recombination, Int cleavage assays with suicide substrates, nuclease protection patterns, gel retardation experiments, and quantitative Western blotting were applied to wild-type attL and attL mutants. The results lead to a model in which one IHF molecule bends the attL DNA and forms a higher order complex with the three bivalent Int molecules required for excisive recombination. It is proposed that each of the Int molecules binds in a unique manner: one bridges two DNA binding sites in cis, one is held via its high affinity amino-terminal DNA binding domain, and the third depends upon protein-protein interactions in addition to its low affinity carboxy-terminal DNA binding domain. This protein-DNA complex contains two unsatisfied DNA binding domains, each with a different sequence specificity, and is well suited to specific interactions with an appropriate recombination partner.     

Specificity determinants for bacteriophage Hong Kong 022 integrase: analysis of mutants with relaxed core-binding specificities

The integrase (Int) proteins encoded by bacteriophages HK022 and lambda catalyse similar site-specific integration and excision reactions between specific DNA regions known as attachment (att) sites. However, the Int proteins of HK022 and lambda are unable to catalyse recombination between non-cognate att sites. The att sites of both phages contain weak binding sites for Int, known as 'core-type' sites. Negatively acting nucleotide determinants associated with specific core sites (lambda B', HK022 B', HK022 C) are responsible for the barrier to non-cognate recombination. In this study, we used challenge phages to demonstrate that the lambda and HK022 Ints cannot bind to core sites containing non-cognate specificity determinants in vivo. We isolated mutants of the HK022 Int, which bind the lambda B' core site. Two mutants, D99N and D99A, have changed a residue in the core-binding (CB) domain, which may be directly contacting the core site DNA. We suggest that binding to the lambda B' site was accomplished by removing the negatively charged aspartate residue, which normally participates in a conflicting interaction with the G4 nucleotide of the lambda B' site. We showed that, although our mutants retain the ability to recombine their cognate att sites, they are unable to recombine lambda att sites.